Embankment design and soil settlement prediction · This method extends in fact the classical...
Transcript of Embankment design and soil settlement prediction · This method extends in fact the classical...
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D-Settlement
Embankment design and soil settlement prediction
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Peat and clay layers will compress significantly
after embankment construction, site preparation
or other loading. A final magnitude of several
metres is not unusual in The Netherlands. Natural
settlements take many years to develop, due to
slow pore water dissipation and creep. Vertical
drains are therefore often applied to speed up the
consolidation process. Temporary preloading and
enforced dewatering are also applied to reduce
the residual creep after the construction period.
Uncertainty and spatial variation will cause the
actual measurements to deviate from the initial
prediction within bounds. Under these complex
circumstances, D-Settlement, (previously known
as MSettle), supplies all necessary means to get
to grips.
General
D-Settlement is practical and easy-to-use software. D-Settlement
quickly predicts the transient settlement and its bandwidth
during the design stage. D-Settlement can automatically improve
this prediction during the construction stage by employing
measurements. D-Settlement offers accurate and robust models,
capturing consolidation, creep, submerging, drains, staged loading,
and unloading and reloading. The dedicated graphical user interface
supports convenient data input and easy interpretation of results.
Reliability is guaranteed by well-established solution methods,
thorough validation, high-level expertise of the developer and a
large user-base. The user documentation includes comprehensive
tutorial examples, to get you started at a glance. Some specific
features in D-Settlement are:
• Design
Automatic determination of the extra soil volume required for
settlement compensation.
• Vertical drains
Input of strip drains, columns and sand walls, based on real
project parameters and layout. Practical options for enforced
dewatering. Automatic conversion to model parameters.
• Consolidation period
Easy determination of the consolidation period for different
vertical drain configurations.
• Safety
Determination of the minimum period required for safe and
stable construction, with the aid of coupled D-Geo Stability.
• Settlement stress
Output of settlement, stress components and water head
components along verticals and along time, as a result from
staged construction and other types of loading (2D/3D).
• Temporary preloading and dewatering
Analysis of the effect of temporary preloading and/or enforced
dewatering on settlements and pore pressures.
• Bandwidth
Output of total bandwidth and residual settlements.
• Fit for settlement plate
Settlement plate fit (automatic or manual), affecting settlements
and bandwidth.
• Horizontal deformation
Output of approximate horizontal deformation along verticals.
D-SettlementEmbankment design and soil settlement prediction
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Output of dissipation graph
Geometry and loading
NEN-Bjerrum model
D-Settlement comes as a standard module, which can be extended
further with other modules to fit more advanced applications:
• D-Settlement Standard module (1D)
• 2D Geometry module
• Darcy module
• Vertical Drains module
• Fit for Settlement Plate module
• Reliability Analyses module
• Horizontal Deformations module.
Standard module (1D)
The standard module is intended for 1D settlement analyses. It
allows input of straightforward projects and provides tabulated
and graphical output of results both on-screen and in a report.
Some specific features include:
Geometry and loading definition
• Direct import of geometry from other Deltares systems tools.
• Manual input of layers, time dependent piezometric levels and
time dependent soil raise via interactive two-dimensional
drawing, or via data entry in specific forms.
• A complete choice of additional uniform, two-dimensional and
three-dimensional loading types, with different shapes.
• Entry of material properties via forms, or direct import from a
central project database.
Soil models with common parameters
D-Settlement calculates the transient 1D settlement along user
defined verticals, with one of the following three soil models:
• NEN-Bjerrum supports the common compression index Cc,
swelling/recompression index Cr and coefficient of secondary
compression Cα. The model and its parameters are based on a small strain assumption. The underlying isotache formulation is
suited for staged loading, unloading and reloading. The concept
was already introduced by Bjerrum in 1968. It implies that the
creep rate increases by loading and reduces by unloading and
by time.
• The Isotache natural strain (a,b,c) model is an extension to
NEN-Bjerrum, by application of a natural strain description.
Natural strain improves predictions in case of large strains.
• Koppejan represents the traditional Dutch model, applicable for
staged loading.
Consolidation
The base modules (1D-2D) includes the quick and approximate
Terzaghi consolidation model. The input parameter is the common
vertical consolidation coefficient. The model multiplies the drained
settlement prediction with a so-called “degree of consolidation”.
The latter follows from a theoretical elastic solution.
Output
After calculation, D-Settlement offers direct access to graphs of
relevant results. All data behind these graphs can also be copied to
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Output of excess head versus time
NEN-Bjerrum model
the clipboard, for instance for use in spreadsheets. Input, warnings
and numerical results are furthermore printed in the report.
Examples of available graphs are:
• graphs of the settlements and different stress and head
components along time and along verticals
• residual settlement versus times at different starting
measurements
• bandwidth indication in the settlement prediction
• dissipation graphs per layer, showing the degree of consolidation
versus time.
2D Geometry module
The basic 1D module supports quick input and settlement
prediction for uniformly loaded soil columns. The 2D module
supports settlement by different loading types along verticals in
full 2D geometries.
Darcy module
The accurate Darcy module is available for improved consolidation
and submerging modelling. This model calculates the coupled
development of excess pore pressure and effective stress
numerically in time. Since D-Settlement Version 8.2, Darcy supports
the same input as the Terzaghi model. Gradual submerging of
initially dry soil is taken into account since then also. A semi-
analytical spatial integration maximizes the speed and robustness.
Vertical Drains module
D-Settlement calculates average heads, based on an assumed
distribution between drains. This method extends in fact the
classical Barron-Carillo method. Supported drain types are wicks,
columns and sand screens, with direct input of their dimensions,
spacing and range. Special features are enforced dewatering,
supporting methods like Menard consolidation, IFCO, BeauDrain,
etc. All drain types can be combined with both consolidation
models.
Fit for Settlement Plate module
D-Settlement offers a module to fit predicted settlements on
measurements during construction. Such a fit can be used to improve
the settlement prognosis for the remainder, as well as to update the
soil properties. D-Settlement uses five practical fit factors for this
purpose. One can opt either for a robust automatic procedure or for
manual adaptation, with the aid of graphical support.
Output of effective stress and settlement versus time
Installation of wick drains
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Reliability Analyses module
Actual settlements will deviate from predictions, due to soil
variability and additional uncertainty. D-Settlement can estimate
the bandwidth in total and residual settlement during the design
stage. D-Settlement can also update and reduce the bandwidth
during the construction stage, after a fit on measurements.
• The crude Monte Carlo method determines the bandwidth in total
and residual settlements, including the exceedance probability
of the allowed residual settlement.
• The First Order Second Moment (FOSM) method is a quick
alternative to approximate the bandwidth in total settlements.
• The iterative First Order Residual Moment (FORM) method is an
alternative to approximate the exceedance probability of the
allowed residual settlement.
Resulting from a reliability analysis is also a graphical overview
of the time dependent sensitivity of settlements, for variation of
uncertain soil parameters.
Horizontal Deformations module
D-Settlement can estimate horizontal deformations in user-defined
verticals, using an elastic solution for a single incompressible
layer. The equivalent elastic stiffness of this layer is an input value.
Interaction with other Deltares systems tools
D-Settlement is part of the Deltares systems product suite.
Therefore, D-Settlement can import soil parameters from a central
project database. D-Settlement can also share its (deformed)
geometry with other Deltares systems programs. Finally,
D-Settlement can directly generate input for the D-Geo Stability
program, including excess pore pressures and deformed geometry.
Support
Deltares systems tools are supported by Deltares. A group of
70 people in software development ensures continuous research
and development. Support is provided by the developers and if
necessary by the appropriate Deltares experts. These experts can
provide consultancy backup as well.
On-line software (VMware)
All popular geotechnical Deltares simulation products are available
over the internet via our Online Software service (Software as
a Service (SaaS)). An internet connection and subscription is
sufficient for worldwide access. Billing is according to the actual
use and subscription costs per quarter.
Direct export to D-Geo Stability
Settlements with bandwidth, before and after the fit
Output of horizontal deformations
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PO Box 1772600 MH DelftBoussinesqweg 12629 HV DelftThe Netherlands
T +31 (0)88 335 81 [email protected]/softwareonlinesoftware.deltares.nl